Real-time observation of frustrated ultrafast recovery from ionization in nanostructured SiO2 Using Laser-Driven Accelerators

J. P. Kennedy, M. Coughlan, C.R.J. Fitzpatrick, H. M. Huddleston, J. Smyth, N. Breslin, H. Donnelly, B. Villagomez-Bernabe, O. N. Rosmej, F. Currell, L. Stella, D. Riley, M. Zepf, M. Yeung, C. L.S. Lewis, B. Dromey*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

7 Downloads (Pure)

Abstract

Ionizing radiation interactions in matter can trigger a cascade of processes that underpin long-lived damage in the medium. To date, however, a lack of suitable methodologies has precluded our ability to understand the role that material nanostructure plays in this cascade. Here, we use transient photoabsorption to track the lifetime of free electrons (τc) in bulk and nanostructured SiO2 (aerogel) irradiated by picosecond-scale (10-12 s) bursts of x rays and protons from a laser-driven accelerator. Optical streaking reveals a sharp increase in τc from <1 ps to >50 ps over a narrow average density (ρav) range spanning the expected phonon-fracton crossover in aerogels. Numerical modeling suggests that this discontinuity can be understood by a quenching of rapid, phonon-assisted recovery in irradiated nanostructured SiO2. This is shown to lead to an extended period of enhanced energy density in the excited electron population. Overall, these results open a direct route to tracking how low-level processes in complex systems can underpin macroscopically observed phenomena and, importantly, the conditions that permit them to emerge.

Original languageEnglish
Article number135001
JournalPhysical Review Letters
Volume133
Issue number13
DOIs
Publication statusPublished - 23 Sept 2024

Keywords

  • Ionizing radiation interactions
  • material nanostructure
  • Frustrated Ultrafast Recovery
  • Laser-Driven Accelerators

ASJC Scopus subject areas

  • General Physics and Astronomy

Fingerprint

Dive into the research topics of 'Real-time observation of frustrated ultrafast recovery from ionization in nanostructured SiO2 Using Laser-Driven Accelerators'. Together they form a unique fingerprint.

Cite this